Pierce Genetics: A Conceptual Approach 3e

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Transcript Pierce Genetics: A Conceptual Approach 3e

Chromosomes and Cellular
Reproduction
• Prokaryote and Eukaryote
• Cell Reproduction
• Sexual Reproduction
Prokaryote
• Unicellular, with no compartmentalized cell
structure.
• Prokaryotic DNA does not exist in the highly
ordered and packed arrangement.
• Made up of eubacteria and archaea.
Eukaryote
• Both unicellular and multicellular with
compartmentalized cell structure.
• Its genetic material is surrounded in a nuclear
envelope to form a nucleus.
• DNA is closely associated with histones to form
tightly packed chromosomes.
Prokaryotic Cell Reproduction
• Simple division: separation of replicated circular
chromosome
• Origin of replication
• High rate of replication
Eukaryotic Cell Replication
• Eukaryotic chromosomes:
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Homologous pair
Chromosome structure
The cell cycle
Genetic consequences of the cell cycle
Homologous Pair
• Diploid cells carry two sets of genetic
information.
• Haploid cells carry one set of genetic
information.
Chromosome Structure
• Centromere: attachment point for spindle
microtubules
• Telomeres: tips of a linear chromosome
• Origins of replication: where the DNA synthesis
begins
The Cell Cycle
• Interphase: an extended period between cell
divisions, DNA synthesis, and chromosome
replication phase
• M phase (mitotic phase)
• Phase check points: key transition points
M phase
• Mitosis: separation of sister chromatids
• Cytokinesis: separation of cytoplasm
Mitosis
• Prophase
• Prometaphase
• Metaphase
• Anaphase
• Telophase
Genetic consequences of the cell cycle
• Producing two cells that are genetically identical
to each other and with the cell that gave rise to
them.
• Newly formed cells contain a full complement of
chromosomes.
• Each newly formed cell contains approximately
half (but not necessarily identical) the cytoplasm
and organelle content of the original parental
cell.
Sexual Reproduction and Genetic Variation
• Meiosis: the production of haploid gametes
• Fertilization: the fusion of haploid gametes
• Genetic variation: consequences of meiosis
Meiosis
• Interphase: DNA synthesis and chromosome
replication phase
• Meiosis I: separation of homologous
chromosome pairs, and reduction of the
chromosome number by half
• Meiosis II: separation of sister chromatids, also
known as equational division
Meiosis I
• Prophase I
• Synapsis: close pairing of homologous
chromosome
• Tetrad: closely associated four sister
chromatids of two homologous chromosomes
• Crossing over: crossing over of chromosome
segments from the sister chromatid of one
chromosome to the sister chromatid of the
other synapsed chromsome – exchange of
genetic information, the first mechanism of
generating genetic variation in newly formed
gametes
Meiosis I
• Metaphase I: random alignment of homologous
pairs of chromosomes along the metaphase
plate
• Anaphase I: separation of homologous
chromosome pairs, and the random distribution
of chromosomes into two newly divided cells –
second mechanism of generating genetics
variation in the newly formed gametes
• Telophase I
• Interkinesis
Meiosis II
• Prophase II
• Metaphase II
• Anaphase II
• Telophase II
Consequences of Meiosis and
Genetic Variation
• Four cells are produced from each original cell.
• Chromosome number in each new cell is
reduced by half. The new cells are haploid.
• Newly formed cells from meiosis are genetically
different from one another and from the parental
cell.
The separation of sister chromatids and
homologous chromosomes
• Cohesin: a protein that holds the chromatids
together and is key to the behavior of
chromosomes in mitosis and meiosis
Meiosis in the Life Cycle of Animals and
Plants
• Meiosis in animals
• Spermatogenesis: male gamete production
• Oogenesis: female gamete production
• Meiosis in plants